CN219973614U - Energy-saving stone curtain wall - Google Patents

Abstract

The utility model discloses an energy-saving stone curtain wall, which comprises a wall body and is arranged along the vertical direction; the framework component is fixedly arranged on one side of the wall body; the wallboard assembly comprises stone plates which are distributed on the same vertical plane in a rectangular array manner and are fixedly connected with the framework assembly, sealing strips which are filled in gaps of adjacent stone plates and are flexible, assembly through grooves are formed in the circumferential outer edges of the stone plates and the face, adjacent to the sealing strips, of each sealing strip, and the sealing strips comprise assembly parts which are matched with the assembly through grooves. According to the energy-saving stone curtain wall, the elastic sealing strips are filled in the gaps between the adjacent stone plates, so that heat transfer between two sides of the wallboard assembly is reduced, heat insulation performance is further enhanced, and energy-saving effect is guaranteed.

Description

Energy-saving stone curtain wall

Technical Field

The utility model relates to the technical field of stone curtain walls, in particular to an energy-saving stone curtain wall.

Background

The stone curtain wall is generally composed of stone panels and supporting structures (beam upright posts, steel structures, connecting pieces and the like), does not bear the load and the action of a main structure, and compared with other building curtain walls, the stone curtain wall combines stone plates with natural textures and thick texture with decorative lines with metallic luster, and can bring the feeling of being very good and lively and foresight to people.

In the prior art, the Chinese patent document with the bulletin number of CN104153494B discloses an energy-saving stone curtain wall, stone plates of the stone curtain wall are directly fixed on a structural reinforced decorative line, so that on one hand, error accumulation is reduced, the flatness of the stone plates is improved, on the other hand, materials used for building the curtain wall are saved, and the construction period is shortened.

However, in the stone curtain wall, gaps exist among the stone plates, so that heat is easily transmitted through the gaps of the stone plates, the heat insulation performance of the stone curtain wall is reduced, and the energy-saving effect is affected; moreover, when the pendant of above-mentioned stone material curtain is connected with the stone material plate, through set up the mounting hole on the pendant roof beam, the screw is equipped with in the mounting hole, screw in nut is fixed on screw circumference outer fringe, because the stone material plate is the platy article, and thickness is limited, leads to the screw to insert the limited degree of depth in the stone material plate, and then has influenced the stability performance that stone material plate and pendant are connected, and after the stone material curtain used for a long time, the easy looseness that appears between pendant and the stone material plate.

Therefore, there is a need for improvements in the prior art energy-saving stone curtain wall.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art and provide the energy-saving stone curtain wall which reduces heat transfer and ensures long-term stability of a structure.

In order to achieve the technical effects, the technical scheme of the utility model is as follows: an energy-saving stone curtain wall, comprising:

the wall body is arranged along the vertical direction;

the framework component is fixedly arranged on one side of the wall body;

the wallboard assembly comprises stone plates which are distributed on the same vertical plane in a rectangular array mode and are fixedly connected with the framework assembly, sealing strips which are filled in gaps of adjacent stone plates and are flexible, assembly through grooves are formed in the circumferential outer edges of the stone plates and one face, adjacent to the sealing strips, of each sealing strip, and the sealing strips comprise assembly parts which are matched with the assembly through grooves.

Preferably, in order to ensure stable connection of the sealing strip and the stone slab, the space in the groove of the assembly through groove comprises a groove opening space adjacent to the groove opening of the assembly through groove and a groove bottom space adjacent to the groove bottom of the assembly through groove, and the width of the groove opening space is smaller than that of the groove bottom space.

Preferably, for convenient assembly, two adjacent stone plates are provided with two assembly through grooves with opposite notches, and the two assembly through grooves have the same shape.

Preferably, in order to facilitate deformation of the sealing tape, the sealing tape has an assembly through hole extending in a longitudinal direction thereof.

Preferably, in order to fix the external size and shape of the sealing strip conveniently, a shaping strip in sealing connection with the circumferential inner wall of the assembly through hole is arranged in the sealing strip, and the shaping strip extends along the length direction of the sealing strip and is a rigid piece.

Preferably, in order to facilitate the accommodation of a portion of the sealing strip after the sealing strip has been deformed by extrusion, the circumferential outer edge of the shaped strip is provided with accommodation holes.

Preferably, in order to ensure firm connection of the stone slab and the framework component, an installation blind hole is formed in one surface of the stone slab adjacent to the wall body, two opposite insertion holes are formed in the circumferential inner wall of the installation blind hole, two insertion holes are respectively inserted with two insertion pieces, a fastener is clamped between the two insertion pieces, and the fastener is fixedly connected with the two insertion pieces and fixedly connected with the framework component.

Preferably, in order to facilitate the fixed connection of the plug connector and the stone slab, the plug connector comprises a plug connector part and a clamping part which are integrally connected, the plug connector part is arranged in the socket, and the clamping part is clamped between the fastener and one of the inner walls of the mounting blind hole.

Preferably, in order to prevent the plug connector from being offset relative to the stone slab, the plug connector is in a strip shape, and the plug connector is clamped between two opposite side walls of the mounting blind hole.

Preferably, in order to realize the connection between skeleton subassembly and the fastener, the skeleton subassembly include with wall body fixed connection just follows the side's pipe that plumb direction extends, be fixed with on the side's pipe along self length direction distribution and with the horizontal fixed unit that same high position stone material plate is connected, horizontal fixed unit includes the horizontal bar that extends along the horizontal direction, the horizontal bar is fixed in the fastener with between the side's pipe.

In summary, compared with the prior art, the energy-saving stone curtain wall disclosed by the utility model has the advantages that the elastic sealing strips are filled in the gaps between the adjacent stone plates, so that the heat transfer between two sides of the wallboard assembly is reduced, the heat insulation performance is further enhanced, and the energy-saving effect is ensured.

Drawings

FIG. 1 is a schematic view of a first embodiment of the present utility model;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is an exploded view of FIG. 1;

FIG. 4 is an exploded view of the other view of FIG. 1;

FIG. 5 is an exploded view of the connection structure of the wall body and the square pipe of the first embodiment;

fig. 6 is an exploded schematic view of the lateral fixation unit of the first embodiment;

fig. 7 is a schematic view of the construction of the first embodiment wallboard assembly;

FIG. 8 is an exploded view of the first embodiment stone slab, sealing strip, fastener attachment structure;

fig. 9 is a rear view of the stone slab of the first embodiment;

FIG. 10 is a cross-sectional view taken along the direction A-A of FIG. 9;

fig. 11 is a schematic view of the construction of a wall panel assembly according to a second embodiment of the present utility model;

FIG. 12 is a side view of FIG. 11;

FIG. 13 is a B-B sectional view of FIG. 12;

FIG. 14 is an exploded view of a second embodiment stone slab, weatherstrip, fastener attachment structure;

in the figure: 100. a wall body; 200. stone plate; 201. assembling a through groove; 202. installing a blind hole; 203. a socket; 300. a sealing strip; 301. assembling the through hole; 400. shaping the strip; 401. a receiving hole; 500. a plug-in component; 501. a plug-in part; 502. a clamping part; 600. a fastener; 700. a vertical fixing unit; 701. square tubes; 702. a first bolt; 703. a first nut; 704. a steel plate; 705. angle steel; 706. a second bolt; 707. a second nut; 800. a lateral fixing unit; 801. a cross bar; 802. pi-shaped steel; 803. a third bolt; 804. a third nut; 805. a fourth bolt; 806. a fourth nut; 900. a fifth bolt; 110. a fifth nut; 120. and a connecting frame.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings and examples. The following examples are only for more clearly illustrating the technical aspects of the present utility model, and are not intended to limit the scope of the present utility model.

First embodiment

As shown in fig. 1 to 10, the energy-saving stone curtain wall according to the first embodiment of the present utility model includes:

a wall body 100, the wall body 100 being arranged in the vertical direction;

the framework component is fixedly arranged on one side of the wall body 100;

the wallboard assembly comprises stone plates 200 which are distributed on the same vertical plane in a rectangular array manner and are fixedly connected with the framework assembly, sealing strips 300 which are filled in gaps of adjacent stone plates 200 and are flexible, assembly through grooves 201 are formed in the circumferential outer edges of the stone plates 200 and the faces, adjacent to the sealing strips 300, of the sealing strips 300, and the sealing strips 300 comprise assembly parts which are matched with the assembly through grooves 201.

In the energy-saving stone curtain wall of the embodiment, the stone plate 200 of the wallboard component is fixedly connected with the wall body 100 through the framework component, the gaps between the adjacent stone plate 200 are filled with the sealing strips 300, the sealing strips 300 are elastic, the sealing strips 300 can elastically deform by themselves to fill the gaps between the adjacent stone plate 200, so that heat is prevented from being transferred between two sides of the stone plate 200, the heat insulation effect is further enhanced, the assembly through grooves 201 are formed in the stone plate 200, the parts of the sealing strips 300 are conveniently filled, and when the assembly is carried out, the assemblies at two ends of the sealing strips 300 are respectively inserted into the two assembly through grooves 201, so that the effect of filling the gaps between the adjacent stone plate 200 is achieved, and heat insulation can be further realized.

Further, the space in the groove where the through groove 201 is assembled includes a groove space adjacent to the groove of the groove itself and a groove bottom space adjacent to the groove bottom of the groove itself, and the width of the groove space is smaller than the width of the groove bottom space. Specifically, the cross section of the assembly through groove 201 is T-shaped, after the structure is adopted, because the groove bottom space width is larger than the groove opening space width, after the assembly part is installed in the assembly through groove 201, the assembly through groove 201 is not easy to be pulled out of the sealing strip 300 along the length direction perpendicular to the assembly through groove 201, and the stable connection of the sealing strip 300 and the assembly through groove 201 is ensured, and of course, the assembly through groove 201 can also be in the structural forms of a dovetail groove, an L-shaped groove, a Y-shaped groove and the like. The sealing strip 300 is preferably a rubber strip or a silicone strip.

Further, two adjacent stone slabs 200 are provided with two assembling through grooves 201 with opposite notches, and the two assembling through grooves 201 have the same shape. After the design is adopted, when the assembly is carried out, the assembly parts on two sides of the sealing strip 300 can be inserted into the adjacent two stone plates 200 to be opposite to the assembly through groove 201, so that the sealing strip 300 and the stone plates 200 are assembled more conveniently, and the construction efficiency is improved.

Further, a blind mounting hole 202 is formed in one surface of the stone slab 200 adjacent to the wall body 100, two opposite insertion holes 203 are formed in the circumferential inner wall of the blind mounting hole 202, two insertion pieces 500 are respectively inserted into the two insertion holes 203, a fastening piece 600 is clamped between the two insertion pieces 500, and the fastening piece 600 is fixedly connected with the two insertion pieces 500 and fixedly connected with the framework component.

Specifically, the hole openings of the mounting blind holes 202 of the stone plate 200 are square, two opposite insertion openings 203 are arranged on the inner top wall and the inner bottom wall of the stone plate, the two insertion openings 203 extend along the horizontal direction, and of course, the two insertion openings 203 can also be respectively arranged on the two vertical inner side walls of the mounting blind holes 202, and at the moment, the insertion openings 203 extend along the vertical direction; the two sockets 203 are respectively arranged on the inner top wall and the inner bottom wall of the mounting blind hole 202 and are respectively connected with the two plug connectors 500, the plug connectors 500 are L-shaped, so that the end parts are inserted into the sockets 203, a fastening piece 600 is clamped between the two plug connectors 500, the top of the fastening piece 600 is abutted against the plug connector 500 above, the bottom of the fastening piece 600 is abutted against the plug connector 500 below, and the fastening piece 600 is fixedly connected with the fifth nut 110 through a fifth bolt 900 in threaded fit.

After the structure is adopted, after the end part of the plug connector 500 is inserted into the socket 203, the fastener 600 is inserted and clamped between the two plug connectors 500, then the fastener 600 is fixedly connected with the plug connector 500 through the fifth bolt 900 and the fifth nut 110, the two plug connectors 500 are prevented from being close to each other while the plug connector 500 and the fastener 600 are fixed, and the end part of the plug connector 500 is inserted into the socket 203 of the stone slab 200, so that the fixed connection between the fastener 600 and the stone slab 200 is realized, and then the fastener 600 is fixedly connected with the framework component, so that the stone slab 200 can be fixedly connected with the wall body 100. Compared with the prior art that bolts are driven into the back of the stone plate 200, the stone plate 200 is convenient to insert the plug connector 500 for fixing through the installation blind holes 202 and the insertion holes 203, and the depth of the insertion holes 203 is larger than the thickness of the stone plate 200, so that the depth of the plug connector 500 inserted into the stone plate 200 is increased, the connection of the plug connector 500, the fastener 600 and the stone plate 200 is reinforced, and the long-term stability of the wallboard assembly structure is ensured.

Further improved is that the plug 500 is strip-shaped, and the plug 500 is clamped between two opposite side walls of the mounting blind hole 202. In this embodiment, the length of the plug 500 is identical to the length of the installation blind hole 202, so, after the end of the plug 500 is inserted into the socket 203 through the installation blind hole 202, two ends of the plug 500 are respectively attached to two vertical inner side walls of the installation blind hole 202, so that the plug 500 and the stone slab 200 are prevented from being relatively offset in the horizontal direction, and stable connection of the plug 500 and the stone slab 200 is further ensured.

Further, the plug 500 includes a plug portion 501 and a clamping portion 502 integrally connected, the plug portion 501 is disposed in the socket 203, and the clamping portion 502 is clamped between the fastener 600 and one of the inner walls of the mounting blind hole 202. Specifically, in this embodiment, the plug 500 is L-shaped, after the assembly is completed, the plug 501 is installed in the socket 203, the clamping portion 502 extends along the horizontal direction, the fastener 600 is a fastening frame, the top and bottom of the fastening frame are respectively and hermetically attached to the two clamping portions 502, the clamping portion 502 of the upper plug 500 is attached to the inner top wall of the mounting blind hole 202, and the clamping portion 502 of the lower plug 500 is attached to the inner bottom of the mounting blind hole 202, so that the firm connection between the plug 500 and the stone slab 200 is ensured.

Further, the framework assembly comprises square pipes 701 fixedly connected with the wall body 100 and extending along the vertical direction, the square pipes 701 are fixedly provided with transverse fixing units 800 distributed along the length direction of the square pipes 701 and connected with the stone slabs 200 at the same height position, the transverse fixing units 800 comprise transverse bars 801 extending along the horizontal direction, and the transverse bars 801 are fixed between the fastening pieces 600 and the square pipes 701.

Specifically, as shown in fig. 2 to 6, the skeleton assembly includes a vertical fixing unit 700 and a horizontal fixing unit 800, and the wall body 100 is fixedly connected with the fastening member 600 in the wallboard assembly sequentially through the vertical fixing unit 700 and the horizontal fixing unit 800.

The vertical fixing unit 700 comprises square pipes 701 extending along the vertical direction, angle steel 705 is arranged on two sides of each square pipe 701, one surface of each angle steel 705 is attached to each square pipe 701, each angle steel 705 is fixedly connected with each second bolt 706 and each second nut 707 through threaded connection, a steel plate 704 attached to each wall 100 is arranged between each wall 100 and each square pipe 701, each wall 100 is fixedly provided with a first bolt 702, each first bolt 702 is an expansion bolt penetrating through each steel plate 704 and is connected with each first nut 703 through threads, each steel plate 704 is fixed to each wall 100, and each steel plate 704 is fixedly connected with each angle steel 705 through welding, so that the square pipes 701 and the walls 100 are fixedly connected.

The transverse fixing unit 800 comprises a transverse bar 801 extending along the horizontal direction, the transverse bar 801 is fixedly connected with the fastener 600 through a fourth bolt 805 and a fourth nut 806 which are in threaded connection, pi-shaped steel 802 is arranged on one side, opposite to the fastener 600, of the transverse bar 801, the pi-shaped steel 802 is fixedly connected with the transverse bar 801 through a third bolt 803 and a third nut 804 which are in threaded connection, the pi-shaped steel 802 is provided with an opening, the inner wall of the opening is welded with three side walls of the circumferential outer edge of the square pipe 701, and therefore the fixed connection of the pi-shaped steel 802 and the square pipe 701 is achieved, the fastener 600 is fixedly connected with the square pipe 701, and further the fixed connection of the wall 100 and the stone slab 200 is achieved.

Second embodiment

As shown in fig. 11 to 14, the energy-saving stone curtain wall of the second embodiment of the present utility model is based on the first embodiment, except that the sealing strip 300 has an assembly through-hole 301 extending in the length direction thereof.

After the structure is adopted, the sealing strip 300 is of a hollow structure, so that the sealing strip 300 is convenient to be inserted into the assembly through groove 201 of the stone plate 200 and deformed, and the circumferential outer edge of the sealing strip 300 is in sealing fit with the circumferential inner wall of the assembly through groove 201.

Further improved is that the sealing strip 300 is internally provided with a shaping strip 400 which is in sealing connection with the circumferential inner wall of the assembly through hole 301, and the shaping strip 400 extends along the length direction of the sealing strip 300 and is a rigid piece. The shaping strip 400 is preferably a plastic strip, on the one hand, the strength is larger than that of the sealing strip 300, on the other hand, the weight is light, compared with a metal piece, the heat insulation performance is strong, the external shape and the size of the sealing strip 300 are favorably fixed through the shaping strip 400, the sealing strip 300 is pre-assembled into the shaping strip 400, then the sealing strip 300 is inserted into the assembly through groove 201, the sealing strip 300 is clamped between the circumferential outer edge of the shaping strip 400 and the circumferential inner wall of the assembly through groove 201, and the stable connection between the sealing strip 300 and the stone plate 200 is ensured.

Further, the circumferential outer edge of the shaping bar 400 is provided with receiving holes 401. Specifically, the plurality of receiving holes 401 are provided and are spaced apart in the longitudinal direction of the shaping bar 400. After the receiving hole 401 is provided, when the sealing strip 300 with the shaping bar 400 is inserted into the assembly through groove 201 of the stone slab 200, the sealing strip 300 is pressed, and a part of the sealing strip can enter the receiving hole 401 of the shaping bar 400, thereby facilitating the loading of the shaping bar 400 into the assembly through groove 201.

In order to reinforce the connection between two adjacent sealing strips 300 in the horizontal direction and two sealing strips 300 in the vertical direction adjacent to the two sealing strips 300, a connecting frame 120 is further provided between the four sealing strips 300, the connecting frame 120 is in a cross shape, and four corners of the connecting frame 120 are inserted into the assembly through holes 301 of the four sealing strips 300 in a sealing manner and are abutted against the ends of the four shaping strips 400. Thus, the four sealing strips 300 are supported by the connecting frame 120 and the four shaping strips 400 to fill gaps of the four stone slabs 200 distributed in the rectangular array, and heat transfer between two sides of the stone slabs 200 is reduced, so that heat preservation and heat insulation effects are improved, and energy conservation is enhanced.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that several modifications and variations can be made without departing from the technical principle of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (10)

1. An energy-saving stone curtain wall, characterized by comprising:

a wall body (100), wherein the wall body (100) is arranged along the vertical direction;

the framework component is fixedly arranged on one side of the wall body (100);

wallboard subassembly, wallboard subassembly including rectangular array distribute in same plumb face and with skeleton subassembly fixed connection's stone material plate (200) and fill in adjacent stone material plate (200) space and be flexible sealing strip (300), stone material plate (200) circumference outer fringe with one side adjacent of sealing strip (300) is provided with assembly through groove (201), sealing strip (300) include with the assembly portion of assembly through groove (201) looks adaptation.

2. The energy-saving stone curtain wall according to claim 1, wherein: the groove space of the assembly through groove (201) comprises a groove opening space adjacent to the groove opening of the assembly through groove and a groove bottom space adjacent to the groove bottom of the assembly through groove, and the width of the groove opening space is smaller than that of the groove bottom space.

3. The energy-saving stone curtain wall according to claim 2, characterized in that: two adjacent stone plates (200) are provided with two assembling through grooves (201) with opposite notches, and the two assembling through grooves (201) are identical in shape.

4. The energy-saving stone curtain wall according to claim 2, characterized in that: the weather strip (300) has an assembly through hole (301) extending in the longitudinal direction thereof.

5. The energy-saving stone curtain wall according to claim 4, wherein: the sealing strip (300) is internally provided with a shaping strip (400) which is in sealing connection with the circumferential inner wall of the assembly through hole (301), and the shaping strip (400) extends along the length direction of the sealing strip (300) and is a rigid piece.

6. The energy-saving stone curtain wall according to claim 5, wherein: the circumferential outer edge of the shaping strip (400) is provided with a receiving hole (401).

7. The energy-saving stone curtain wall according to claim 1, wherein: the stone slab (200) with one side adjacent to wall body (100) is provided with installation blind hole (202), be provided with two jack (203) just right on the circumference inner wall of installation blind hole (202), two jack (203) have inserted two plug connector (500) respectively, two it has fastener (600) to press from both sides between plug connector (500), fastener (600) with two plug connector (500) fixed connection just with skeleton subassembly fixed connection.

8. The energy-saving stone curtain wall according to claim 7, wherein: the plug connector (500) comprises a plug portion (501) and a clamping portion (502) which are integrally connected, the plug portion (501) is arranged in the socket (203), and the clamping portion (502) is clamped between the fastener (600) and one of inner walls of the mounting blind hole (202).

9. The energy-saving stone curtain wall according to claim 7, wherein: the plug connector (500) is in a strip shape, and the plug connector (500) is clamped between two opposite side walls of the mounting blind hole (202).

10. The energy-saving stone curtain wall according to claim 7, wherein: the framework assembly comprises square pipes (701) fixedly connected with the wall body (100) and extending along the vertical direction, transverse fixing units (800) distributed along the length direction of the square pipes (701) and connected with stone plates (200) at the same height position are fixed on the square pipes, each transverse fixing unit (800) comprises a transverse bar (801) extending along the horizontal direction, and each transverse bar (801) is fixed between the corresponding fastener (600) and each square pipe (701).